Membrane phospholipid catabolism and Ca2+ activity in control of senescence

Leshem, Y. Y. 1987. Membrane phospholipid catabolism and Ca²⁺ activity in control of senescence. A key role in the regulation of plant development and senescence appears to be a finely balanced equilibrium between membrane phospholipid catabolism on the one hand, and synthesis and remodelling on the other. In the catabolic “phosphatidyl-linoleyl(-enyl) cascade”, entering of Ca²⁺ into the cytosol triggers the catabolic process by binding to calmodulin and activating phospholipase A₂, (EC 3.1.1.4). The latter proceeds to release linoleic or linolenic acid from the sn-2 (stereospecific numbering) location of intact phospholipid, thus providing substrate for lipoxygenase (EC 1.13.11.12). The action of lipoxygenase then generates a series of oxy-free radicals, ethylene, endogenous Ca²⁺ ionophores, malondialdehyde and jasmonic acid. These may recycle to the membrane, causing the entry of more Ca²⁺ and induction of a further, identical catabolic cycle. With increased cycling, membranes become progressively senescent and undergo biophysical changes altering microviscosity, fluidity, phase configurations of membrane phospholipids and transition temperatures. The cascade does not appear to be specific for the phospholipid substrate, and it is envisaged that besides phospholipase A₂, both phospholipase B (EC 3.1.1.5) and lipolytic acylhydrolase could participate in the process. A parallel process counteracting the above, is membrane remodelling and turnover, proceeding initially by the same Ca²⁺- and possibly calmodulin-triggering, but leading via phospholipase C (EC 3.1.4.10) action and diacylglycerol formation to protein kinase activation and proton pump recharging. It is speculated that auxin and cytoki-nin, albeit by different pathways, induce this route, for which membrane phospho-inositides may be the preferred membrane-associated phospholipid substrate.     

Freezing Injury and Phospholipid Degradation in Vivo in Woody Plant Cells: III. Effects of Freezing on Activity of Membrane-bound Phospholipase D in Microsome-enriched Membranes

Freeze-thawing of microsome-enriched membranes from living bark tissues of black locust trees, especially those from less hardy tissues, caused a drastic increase in sensitivity to Ca²⁺ and a complete loss of the regulatory action of Mg²⁺ in membrane-bound phospholipase D activity with endogenous (membrane-bound) substrates. Also, the freeze-thaw cycle made phospholipase D in these membranes more resistant to digestion by proteases. Thus, the regulatory properties of the membrane-bound phospholipase D seem to be dependent on the nature of the membranes and on the interaction between the enzyme and membranes as well. The alteration of regulatory properties by freezing was protected by sucrose, at lower concentrations, and more effectively for membranes from hardy tissues than for membranes from less hardy tissue. Addition of partially purified soluble phospholipase D to the reaction system containing membranes caused only a slight stimulation of the degradation of endogenous phospholipids. Phospholipid degradation in vivo during freezing of less hardy tissue may be catalyzed mainly by the bound enzyme. Disintegration of the tonoplast, however, besides releasing soluble phospholipase D into the cytosol, would release organic acids (lowering the pH) and free Ca²⁺. Both factors would stimulate drastically the membrane-bound phospholipase D, causing degradation of membrane phospholipids.     

Differences in the pattern of attack of acidic,neutral, and basic phospholipases A2 of A. halys blomhofii on human erythrocyte membranes: Problems in interpretation of phospholipid location

Purified acidic (pI 4.9), neutral (pI 6.9), and basic (pI 8.7) phospholipase A₂ from Agkistrodon halys blomhofii showed characteristically different patterns of hemolysis and phospholipid hydrolysis of intact human erthyrocytes. Acidic and neutral enzymes were nonlytic in the early periods of incubations with intact erythrocytes whereas the basic enzyme caused immediate hemolysis (5–8%). Under nonlytic conditions acidic and neutral enzymes hydrolyzed only phosphatidyl choline (PC) (20 and 50%, respectively), whereas basic enzyme hydrolyzed not only PC (60%) but nearly 15% of the phosphatidylethanolamine (PE). Both PC and PE were hydrolyzed significantly when the three phospholipases A₂ were incubated individually with erythrocyte lysate or hypotonic ghosts (sealed or unsealed). The order of substrate preference for acidic and neutral enzymes was always PC > PE. On the contrary basic enzyme exhibited the property of substrate specificity reversal. It hydrolyzed PC faster than PE when the membranes were sealed whereas PE hydrolysis was faster than PC hydrolysis in unsealed membranes. Interestingly only the basic enzyme showed activity in the absence of Ca²⁺ and in the presence of 0.5 mm EDTA. Phospholipase C (Bacillus cereus or Clostridium perfringens) did not show the property of substrate specificity reversal although their ability to hydrolyze PC and PE was different. In general this study demonstrates the unique activity patterns of three physically different pure phospholipases A₂ on human erythrocyte membranes which could be of value in selectively modifying membrane phospholipids. In addition it also throws an important light on the fact that results obtained with phospholipases should be interpreted with caution particularly as regards the localization of phospholipids in membranes.     

Further characterization of Ca2+-activated phospholipase A2 in cat adrenal cortex

When cat adrenocortical cells were incubated with exogenous phospholipid substrate (autoclaved $\text{E.}$$\text{coli}$) in the presence of corticotropin, there was a Ca²⁺-dependent increase in phospholipid breakdown activity, suggesting that a hormone-stimulated phospholipase is localized to the plasma membrane. Phospholipase activity in a particulate fraction from lysed cells at neutral pH was a function of the Ca²⁺ concentration. The addition of increasing Ca²⁺ concentrations to a subcellular fraction of lysed cells which had been prelabelled with [¹⁴C]arachidonic acid produced graded increases in fatty acid release. A depletion of label from phosphatidylcholine was observed, as well as a marked increase in radioactivity associated with phosphatidylethanolamine. The subcellular fraction of cells prelabelled with [¹⁴C]palmitic acid failed to release fatty acid in response to Ca²⁺, although a loss of label from phosphatidylcholine and a modest gain in label by phosphatidylethanolamine was demonstrable. A Ca²⁺-activated deacylation-reacylation reaction preferentially involving phosphatidylethanolamine was evident in cortical cells prelabelled with archidonic acid; whereas, other Ca²⁺-stimulated lipolytic reactions also appeared to be operative in cells prelabelled with either arachidonic or palmitic acid. The Ca²⁺-dependent mobilization of arachidonic acid from an endogenous phospholipid pool lends additional support to the idea that Ca²⁺-mediated activation of phospholipase A₂ participates in the control of adrenocortical activity. However, since Ca²⁺ also stimulated arachidonic acid liberation from cortical triglycerides, these lipid moieties may also contribute to the observed effects of Ca²⁺ on fatty acid release.     

Effect of membrane sterol content on the susceptibility of phospholipids to phospholipase A2

The effects of membrane sterol level on the susceptibility of LM cell plasma membranes to exogenous phospholipases A2 has been investigated. Isolated plasma membranes, containing normal or decreased sterol content, were prepared from mutant LM cell sterol auxotrophs. beta-Bungarotoxin-catalyzed hydrolysis of both endogenous phospholipids and phospholipids introduced into the membranes with beef liver phospholipid exchange proteins was monitored. In both cases, phosphatidylcholine (PC) and phosphatidylethanolamine (PE) were degraded at similar rates in normal membranes, while PC hydrolysis was specifically accelerated in sterol-depleted membranes. Additional data suggest that this preferential hydrolysis of PC is not a consequence of the phospholipid head group specificity of the phospholipase, nor of a difference in the accessibility of PC versus PE to the enzyme. Analysis of the reaction products formed during treatment of isolated membranes with phospholipase A2 showed almost no accumulation of lysophospholipids. This was found to be due to highly active lysophospholipase(s), present in LM cell plasma membranes, acting on the lysophospholipids formed by phospholipase A2 action. A soluble phospholipase A2 was partially purified from LM cells and found to behave as beta-bungarotoxin with regard to membrane sterol content. These results demonstrate that the nature of phospholipid hydrolysis, catalyzed by phospholipase A2, can be significantly affected by membrane lipid composition.     

Specific release of plasma membrane enzymes by a phosphatidylinositol-specific phospholipase C

The release of plasma membrane ecto-enzymes by a phosphatidylinositol-specific phospholipase C from Staphylococcus aureus was investigated. There was no effect on l-leucyl-β-naphthylamidase, alkaline phosphodiesterase I and Ca²⁺- or Mg²⁺-ATPase, but substantial proportions of the alkaline phosphatase and 5′-nucleotidase were released. There was no simultaneous release of phospholipid and the solubilized enzymes were not excluded from Sepharose 6-B. It was therefore concluded that release was not a secondary consequence of membrane vesiculation but occurred as a result of the disruption of specific interactions involving the phosphatidylinositol molecule.     

Melittin-Induced Lipid Extraction Modulated by the Methylation Level of Phosphatidylcholine Headgroups

Protein- and peptide-induced lipid extraction from membranes is a critical process for many biological events, including reverse cholesterol transport and sperm capacitation. In this work, we examine whether such processes could display specificity for some lipid species. Melittin, the main component of dry bee venom, was used as a model amphipathic α-helical peptide. We specifically determined the modulation of melittin-induced lipid extraction from membranes by the change of the methylation level of phospholipid headgroups. Phosphatidylcholine (PC) bilayers were demethylated either by substitution with phosphatidylethanolamine (PE) or chemically by using mono- and dimethylated PE. It is shown that demethylation reduces the association of melittin with membranes, likely because of the resulting tighter chain packing of the phospholipids, which reduces the capacity of the membranes to accommodate inserted melittin. This reduced binding of the peptide is accompanied by an inhibition of the lipid extraction caused by melittin. We demonstrate that melittin selectively extracts PC from PC/PE membranes. This selectivity is proposed to be a consequence of a PE depletion in the surroundings of bound melittin to minimize disruption of the interphospholipid interactions. The resulting PC-enriched vicinity of melittin would be responsible for the observed formation of PC-enriched lipid/peptide particles resulting from the lipid efflux. These findings reveal that modulating the methylation level of phospholipid headgroups is a simple way to control the specificity of lipid extraction from membranes by peptides/proteins and thereby modulate the lipid composition of the membranes.     

Promotion of photosynthesis in transgenic rice over-expressing of maize C4 phosphoenolpyruvate carboxylase gene by nitric oxide donors

We determined the effects of exogenous nitric oxide on photosynthesis and gene expression in transgenic rice plants (PC) over-expressing the maize C₄ pepc gene, which encodes phosphoenolpyruvate carboxylase (PEPC). Seedlings were subjected to treatments with NO donors, an NO scavenger, phospholipase inhibitors, a Ca²⁺ chelator, a Ca²⁺ channel inhibitor, and a hydrogen peroxide (H₂O₂) inhibitor, individually and in various combinations. The NO donors significantly increased the net photosynthetic rate (P_N) of PC and wild-type (WT), especially that of PC. Treatment with an NO scavenger did inhibit the P_N of rice plants. The treatments with phospholipase inhibitors and a Ca²⁺ chelator decreased the P_N of WT and PC, and photosynthesis was more strongly inhibited in WT than in PC. Further analyses showed that the NO donors increased endogenous levels of NO and PLD activity, but decreased endogenous levels of Ca²⁺ both WT and PC. However, there was a greater increase in NO in WT and a greater increase in PLD activity and Ca²⁺ level in PC. The NO donors also increased both PEPC activity and pepc gene expression in PC. PEPC activity can be increased by SNP alone. But the expression of its encoding gene in PC might be regulated by SNP, together with PA and Ca²⁺.     

Calcium- and calmodulin-regulated breakdown of phospholipid by microsomal membranes from bean cotyledons

Evidence for the involvement of Ca²⁺ and calmodulin in the regulation of phospholipid breakdown by microsomal membranes from bean cotyledons has been obtained by following the formation of radiolabeled degradation products from [U-¹⁴C]phosphatidylcholine. Three membrane-associated enzymes were found to mediate the breakdown of [U-¹⁴C] phosphatidylcholine, viz. phospholipase D (EC 3.1.4.4), phosphatidic acid phosphatase (EC 3.1.3.4), and lipolytic acyl hydrolase. Phospholipase D and phosphatidic acid phosphatase were both stimulated by physiological levels of free Ca²⁺, whereas lipolytic acyl hydrolase proved to be insensitive to Ca²⁺. Phospholipase D was unaffected by calmodulin, but the activity of phosphatidic acid phosphatase was additionally stimulated by nanomolar levels of calmodulin in the presence of 15 micromolar free Ca²⁺. Calmidazolium, a calmodulin antagonist, inhibited phosphatidic acid phosphatase activity at IC₅₀ values ranging from 10 to 15 micromolar. Thus the Ca²⁺-induced stimulation of phosphatidic acid phosphatase appears to be mediated through calmodulin, whereas the effect of Ca²⁺ on phospholipase D is independent of calmodulin. The role of Ca²⁺ as a second messenger in the initiation of membrane lipid degradation is discussed.     

Improvement of the anoxia-induced mitochondrial dysfunction by membrane modulation

The mitochondrial dysfunction induced by anoxia in vitro was improved with chlorpromazine, cepharanthine, bromophenacyl bromide, and mepacrine without affecting phospholipid or adenine nucleotide metabolisms. The drugs inhibited lipid peroxidation by Fe²⁺, mitochondrial disruption by Ca²⁺, and membrane perturbation by lysolecithin, and retained the activity to control H⁺ permeability across mitochondrial membranes. The drugs appeared to preserve the functions by acting to suppress the development of membrane deterioration which may have resided in the deenergization of mitochondria in the absence of oxygen.     

Intracellular- and extracellular-derived Ca influence phospholipase A2-mediated fatty acid release from brain phospholipids

Docosahexaenoic acid (DHA) and arachidonic acid (AA) are found in high concentrations in brain cell membranes and are important for brain function and structure. Studies suggest that AA and DHA are hydrolyzed selectively from the sn-2 position of synaptic membrane phospholipids by Ca²⁺-dependent cytosolic phospholipase A₂ (cPLA₂) and Ca²⁺-independent phospholipase A₂ (iPLA₂), respectively, resulting in increased levels of the unesterified fatty acids and lysophospholipids. Cell studies also suggest that AA and DHA release depend on increased concentrations of Ca²⁺, even though iPLA₂ has been thought to be Ca²⁺-independent. The source of Ca²⁺ for activation of cPLA₂ is largely extracellular, whereas Ca²⁺ released from the endoplasmic reticulum can activate iPLA₂ by a number of mechanisms. This review focuses on the role of Ca²⁺ in modulating cPLA₂ and iPLA₂ activities in different conditions. Furthermore, a model is suggested in which neurotransmitters regulate the activity of these enzymes and thus the balanced and localized release of AA and DHA from phospholipid in the brain, depending on the primary source of the Ca²⁺ signal.     

The role of ion-lipid interactions and lipid packing in transient defects caused by phenolic compounds

The transient disruption of membranes for the passive permeation of ions or small molecules is a complex process relevant to understanding physiological processes and biotechnology applications. Phenolic compounds are widely studied for their antioxidant and antimicrobial properties, and some of these activities are based on the interactions of the phenolic compound with membranes. Ions are ubiquitous in cells and are known to alter the structure of phospholipid bilayers. Yet, ion-lipid interactions are usually ignored when studying the membrane-altering properties of phenolic compounds. This study aims to assess the role of Ca²⁺ ions on the membrane-disrupting activity of two phenolic acids and to highlight the role of local changes in lipid packing in forming transient defects or pores. Results from tethered bilayer lipid membrane electrical impedance spectroscopy experiments showed that Ca²⁺ significantly reduces membrane disruption by caffeic acid methyl ester and caffeic acid. As phenolic acids are known metal chelators, we used UV-vis and fluorescence spectroscopy to exclude the possibility that Ca²⁺ interferes with membrane disruption by binding to the phenolic compound and subsequently preventing membrane binding. Molecular dynamics simulations showed that Ca²⁺ but not caffeic acid methyl ester or caffeic acid increases lipid packing in POPC bilayers. The combined data confirm that Ca²⁺ reduces the membrane-disrupting activity of the phenolic compounds, and that Ca²⁺-induced changes to lipid packing govern this effect. We discuss our data in the context of ion-induced pores and transient defects and how lipid packing affects membrane disruption by small molecules.     

Inhibition of phospholipase A2 and phospholipase C by polyamines

The polyamines spermine, spermidine, and putrescine inhibit the activity of phospholipase A₂ (Naja naja) and phospholipase C (Clostridium welchii) on phospholipid vesicles and mitochondrial membranes as sources of substrate phospholipids. The inhibitory effect is highest for spermine and lowest for putrescine. With both enzymes, inhibition is stronger when phospholipid vesicles rather than mitochondrial membranes are used as the substrate. No clear competition of polyamines with Ca²⁺, which is required for the activity of both enzymes, has been observed. The inhibition appears to be due to steric hindrance of enzyme-substrate interaction due to the binding of the organic polycations to the phospholipid bilayer.     

Transient Receptor Potential Canonical Type 1 (TRPC1) Operates as a Sarcoplasmic Reticulum Calcium Leak Channel in Skeletal Muscle

Extensive studies performed in nonexcitable cells and expression systems have shown that type 1 transient receptor potential canonical (TRPC1) channels operate mainly in plasma membranes and open through phospholipase C-dependent processes, membrane stretch, or depletion of Ca²⁺ stores. In skeletal muscle, it is proposed that TRPC1 channels are involved in plasmalemmal Ca²⁺ influx and stimulated by store depletion or membrane stretch, but direct evidence for TRPC1 sarcolemmal channel activity is not available. We investigated here the functional role of TRPC1 using an overexpressing strategy in adult mouse muscle fibers. Immunostaining for endogenous TRPC1 revealed a striated expression pattern that matched sarcoplasmic reticulum (SR) Ca²⁺ pump immunolabeling. In cells expressing TRPC1-yellow fluorescent protein (YFP), the same pattern of expression was observed, compatible with a longitudinal SR localization. Resting electric properties, action potentials, and resting divalent cation influx were not altered in TRPC1-YFP-positive cells. Poisoning with the SR Ca²⁺ pump blocker cyclopiazonic acid elicited a contracture of the fiber at the level of the overexpression site in presence and absence of external Ca²⁺ which was not observed in control cells. Ca²⁺ measurements indicated that resting Ca²⁺ and the rate of Ca²⁺ increase induced by cyclopiazonic acid were higher in the TRPC1-YFP-positive zone than in the TRPC1-YFP-negative zone and control cells. Ca²⁺ transients evoked by 200-ms voltage clamp pulses decayed slower in TRPC1-YFP-positive cells. In contrast to previous hypotheses, these data demonstrate that TRPC1 operates as a SR Ca²⁺ leak channel in skeletal muscle.     

Role of divalent cations and ascorbate in photochemical activities of Anacystis membranes

Photosynthetic membrane fragments were prepared from Anacystis nidulans by French pressure cell disruption. Ascorbate was required to stabilize photophosphorylation activity in membranes kept at near 0°C. Divalent cations were required during mechanical disruption and during assays for Photosystem II activity, with Ca²⁺ serving best. The rate of photophosphorylation was severely inhibited by Ca²⁺ during assays. Results suggest that best rates are achieved when photosynthetic membranes contain Ca²⁺ exposed to the interior surface, facilitating Photosystem II activity, and Mg²⁺ exposed to the exterior surface during assays, facilitating photophosphorylation activity.     

Partial purification and characterization of phosphatidic acid-specific phospholipase A1 in porcine platelet membranes

We have shown previously that the phospholipase A (PLA) activity specific for phosphatidic acid (PA) in porcine platelet membranes is of the A₁ type (PA-PLA₁) [J. Biol. Chem. 259 (1984) 5083]. In the present study, the PA-PLA₁ was solubilized in Triton X-100 from membranes pre-treated with 1 M NaCl, and purified 280-fold from platelet homogenates by sequential chromatography on blue-Toyopearl, red-Toyopearl, DEAE-Toyopearl, green-agarose, brown-agarose, polylysine-agarose, palmitoyl-CoA-agarose and blue-5PW columns. In the presence of 0.1% Triton X-100 in the assay mixture, the partially purified enzyme hydrolyzed the acyl group from the sn-1 position of PA independently of Ca²⁺ and was highly specific for PA; phosphatidylcholine (PC), phosphatidylethanolamine (PE), phosphatidylserine (PS), and phosphatidylinositol (PI) were poor substrates. The enzyme exhibited lysophospholipase activity for l-acyl-lysoPA at 7% of the activity for PA hydrolysis but no lipase activity was observed for triacylglycerol (TG) and diacylglycerol (DG). At 0.025% Triton X-100, the enzyme exhibited the highest activity, and PA was the best substrate, but PE was also hydrolyzed substantially. The partially purified PA-PLA₁ in porcine platelet membranes was shown to be different from previously purified and cloned phospholipases and lipases by comparing the sensitivities to a reducing agent, a serine-esterase inhibitor, a PLA₂ inhibitor, a Ca²⁺-independent phospholipase A₂ inhibitor, and a DG lipase inhibitor.     

Characterization of the human tumor suppressors TIG3 and HRASLS2 as phospholipid-metabolizing enzymes

Tazarotene-induced protein 3 (TIG3) and HRAS-like suppressor family 2 (HRASLS2) exhibit tumor-suppressing activities and belong to the lecithin retinol acyltransferase (LRAT) protein family. Since Ca²⁺-independent N-acyltransferase and H-rev107 (another tumor suppressor), both of which are members of the LRAT family, have been recently reported to possess catalytic activities related to phospholipid metabolism, we examined possible enzyme activities of human TIG3 and HRASLS2 together with human H-rev107. The purified recombinant proteins of TIG3, HRASLS2, and H-rev107 functioned as phospholipase (PL) A_1/2 in a Ca²⁺-independent manner with maximal activities of 0.53, 0.67, and 2.57 μmol/min/mg of protein, respectively. The proteins were active with various phosphatidylcholines (PCs) and phosphatidylethanolamines (PEs), and for most of substrates the PLA₁ activity was much higher than the PLA₂ activity. In addition, HRASLS2 catalyzed N-acylation of PE to form N-acyl-PE and O-acylation of lyso PC to form PC. TIG3 and H-rev107 catalyzed the N-acylation and O-acylation at relatively low rates. Moreover, these three proteins showed different expression profiles in human tissues. These results suggest that the tumor suppressors TIG3, HRASLS2 and H-rev107 are involved in the phospholipid metabolism with different physiological roles.     

Freezing Injury and Phospholipid Degradation in Vivo in Woody Plant Cells: II. Regulatory Effects of Divalent Cations on Activity of Membrane-bound Phospholipase D

Activity of membrane-bound phospholipase D in microsomes from bark tissues of black locust tree (Robina pseudoacacia L.) was demonstrated to be regulated by a competitive binding of divalent cations. Binding of Ca²⁺ at high concentrations (1 to 50 millimolar) modified the pH activity profile, shifting the optimum pH by 0.5 unit toward neutral and increasing the activity in the neutral pH. Mg²⁺, on the other hand, inhibited the reaction of membrane-bound phospholipase D without added Ca²⁺, and competitively inhibited the Ca²⁺ stimulation. The regulatory effects of those ions were dependent on pH. Reduction in pH resulted in a decrease in the apparent dissociation constant for Ca²⁺ and an increase in that for Mg²⁺. From Lineweaver-Burk double reciprocal plots of Ca²⁺ and the initial velocity, it was suggested that the binding of Ca²⁺ in the higher concentration resulted in nearly the same conformational change of enzyme as reduction in pH. Mg²⁺, on the other hand, counteracted those effects of Ca²⁺ and lower pH on the enzyme conformation in such a manner as to inactivate. The membrane-bound phospholipase D because more sensitive to Ca²⁺ and less sensitive to Mg²⁺ as the hardiness of the tissues decreased. This fact may indicate that some qualitative changes in membranes are involved in the hardiness changes and also in the susceptibility of phospholipid to degradation by phospholipase D in plant cells.     

Lipids and lipolytic enzyme activities of rat heart mitochondria

The lipid composition and lipolytic enzyme activities in rat cardiac mitochondria were examined. Subsarcolemmal mitochondria were prepared by treatment of heart muscle with a Polytron tissue processor, while interfibrillar mitochondria were released by exposure of the remaining low-speed pellet to the protease, nagarse. These procedures are known to yield two functionally different populations of mitochondria. However, their phospholipid contents and compositions were identical, as were the positional distributions of the constituent fatty acids. Of the ethanolamine phospholipids, 20% were plasmalogens, and about 2% of the choline phospholipids consisted of this alkenylacyl species. Both subsarcolemmal and interfibrillar mitochondria contained a Ca²⁺-activated phospholipase A₂, as evidenced by the Ca²⁺-dependent release of unsaturated fatty acids and lysophosphatidylethanolamine from endogenous lipids. Ruthenium red prevented the activation of this enzyme by Ca²⁺, indicating that the activity is located in the matrix space or associated with the inner surface of the inner membrane. Both mitochondrial fractions produced free fatty acids and lysophosphatidylethanolamine in the absence of free Ca²⁺ apparently due to an outer membrane phospholipase A₁. The activity of this enzyme decreased with time, particularly in interfibrillar mitochondria, providing that Ca²⁺ was absent. Nagarse treatment of subsarcolemmal mitochondria resulted in a preparation with the same phospholipase A₁ properties as interfibrillar mitochondria. The possibility that differences in phospholipase A₁ properties account for some of the functional variations between the two mitochondrial types is discussed.     

Changes of Some Membrane-Associated Enzyme Activities Degradation of Membrane Phospholipids in Cucumber Roots Due to Ca2+ Starvation

Deprivation of Ca²⁺ from a complete culture medium affectedthe enzyme activities associated with five membrane fractionsof cucmber roots obtained by discontinuous sucrose density gradientcentrifugation. The total activity of K⁺-ATPase, Cyt. c oxidaseand NADPH-Cyt. c reductase of Ca²⁺-deficient roots, starvedfor only 4 days, had decreased to 14, 38 and 60% of the activityof the control roots. In general, loss of enzyme activitieswas accompanied by a shift of activity distribution from theheavier density fractions to lighter ones. The amounts of Ca²⁺ associated with membranes from Ca²⁺-starvedroots decreased to 50–60% of those of the control roots.Both phospholipid and neutral lipid contents in the membranesdecreased markedly while the protein content was not changedby Ca²⁺ deficiency. Phospholipid analysis indicated a drasticdrop in the percent composition of phosphatidylinositol butan increase of phosphatidic acid. Also, phospholipase D activityincreased remarkably during Ca²⁺ starvation, paralleling theappearance of Ca²⁺-deficiency symptoms. Thus, the major effects of Ca²⁺ deficiency appear to be to stimulatephospholipase D activity and a reduction in membrane bound Ca²⁺.These effect may be involved in disorganization of the membranestructure and the changes of enzyme activities associated withthe altered membranes. ¹Rubber Research Institute of Sri Lanka, Dartonfield, Agalwatta,Sri Lanka. (Received July 15, 1985; Accepted November 21, 1985)